boost_1_45_0/libs/spirit/example/karma/printf_style_double_format.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 //  Copyright (c) 2001-2010 Hartmut Kaiser
 //
 //  Distributed under the Boost Software License, Version 1.0. (See accompanying
 //  file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)

 //  The main purpose of this example is to show how a single container type can
 //  be formatted using different output grammars.

 #include <boost/config/warning_disable.hpp>
 #include <boost/spirit/include/qi.hpp>
 #include <boost/spirit/include/karma.hpp>
 #include <boost/fusion/include/adapt_struct.hpp>

 #include <cmath>

 using namespace boost::spirit;

 ///////////////////////////////////////////////////////////////////////////////
 // This policy allows to use printf style formatting specifiers for Karma
 // floating point generators. This policy understands the following format:
 //
 //  The format string must conform to the following format, otherwise a
 //  std::runtime_error will be thrown:
 //
 //      %[flags][fill][width][.precision]type
 //
 //  where:
 //      flags (only one possible):
 //          +:      Always denote the sign '+' or '-' of a number
 //          -:      Left-align the output
 //      fill:
 //          0:      Uses 0 instead of spaces to left-fill a fixed-length field
 //      width:
 //          number: Left-pad the output with spaces until it is at least number
 //                  characters wide. if number has a leading '0', that is
 //                  interpreted as a 'fill', the padding is done with '0'
 //                  characters instead of spaces.
 //      precision:
 //          number: Causes the decimal portion of the output to be expressed
 //                  in at least number digits
 //      type (only one possible):
 //          e:      force scientific notation, with a lowercase "e"
 //          E:      force scientific notation, with a uppercase "E"
 //          f:      floating point format
 //          g:      use %e or %f, whichever is shorter
 //          G:      use %E or %f, whichever is shorter
 //

 ///////////////////////////////////////////////////////////////////////////////
 // define a data structure and a corresponding parser to hold the formatting
 // information extracted from the format specification string
 namespace client
 {
     struct format_data
     {
         char flag;
         char fill;
         int width;
         int precision;
         char type;
     };
 }

 // We need to tell fusion about our format_data struct
 // to make it a first-class fusion citizen
 BOOST_FUSION_ADAPT_STRUCT(
     client::format_data,
     (char, flag)
     (char, fill)
     (int, width)
     (int, precision)
     (char, type)
 )

 namespace client
 {
     ///////////////////////////////////////////////////////////////////////////
     // Grammar for format specification string as described above
     template <typename Iterator>
     struct format_grammar : qi::grammar<Iterator, format_data()>
     {
         format_grammar() : format_grammar::base_type(format)
         {
             using qi::uint_;
             using qi::attr;
             using ascii::char_;
             using ascii::no_case;

             format %= '%' >> flags >> fill >> width >> prec >> type;

             // default flags is right aligned
             flags  = char_('+') | char_('-') | attr(' ');
             fill   = char_('0') | attr(' ');     // default fill is space
             width  = uint_ | attr(-1);
             prec   = '.' >> uint_ | attr(3);     // default is 3 digits
             type   = no_case[char_('e')] | char_('f') | no_case[char_('g')];
         };

         qi::rule<Iterator, format_data()> format;
         qi::rule<Iterator, char()> flags;
         qi::rule<Iterator, char()> fill;
         qi::rule<Iterator, int()> width;
         qi::rule<Iterator, int()> prec;
         qi::rule<Iterator, char()> type;
     };
 }

 ///////////////////////////////////////////////////////////////////////////////
 // real_policies implementation allowing to use a printf style format
 // specification for Karma floating pointing number generators
 template <typename T>
 struct format_policies : karma::real_policies<T>
 {
     typedef karma::real_policies<T> base_policy_type;

     ///////////////////////////////////////////////////////////////////////////
     //  This real_policies implementation requires the output_iterator to
     //  implement buffering and character counting. This needs to be reflected
     //  in the properties exposed by the generator
     typedef boost::mpl::int_<
         karma::generator_properties::countingbuffer
     > properties;

     ///////////////////////////////////////////////////////////////////////////
     format_policies(char const* fmt = "%f")
     {
         char const* last = fmt;
         while (*last)
             last++;

         client::format_grammar<char const*> g;
         if (!qi::parse(fmt, last, g, format_))
             throw std::runtime_error("bad format string");
     }

     ///////////////////////////////////////////////////////////////////////////
     //  returns the overall format: scientific or fixed
     int floatfield(T n) const
     {
         if (format_.type == 'e' || format_.type == 'E')
             return base_policy_type::fmtflags::scientific;

         if (format_.type == 'f')
             return base_policy_type::fmtflags::fixed;

         BOOST_ASSERT(format_.type == 'g' || format_.type == 'G');
         return this->base_policy_type::floatfield(n);
     }

     ///////////////////////////////////////////////////////////////////////////
     //  returns whether to emit a sign even for non-negative numbers
     bool const force_sign(T) const
     {
         return format_.flag == '+';
     }

     ///////////////////////////////////////////////////////////////////////////
     //  returns the number of required digits for the fractional part
     unsigned precision(T) const
     {
         return format_.precision;
     }

     ///////////////////////////////////////////////////////////////////////////
     //  emit the decimal dot
     template <typename OutputIterator>
     static bool dot (OutputIterator& sink, T n, unsigned precision)
     {
         // don't print the dot if no fractional digits are to be emitted
         if (precision == 0)
             return true;
         return base_policy_type::dot(sink, n, precision);
     }

     template <typename CharEncoding, typename Tag, typename OutputIterator>
     bool exponent (OutputIterator& sink, long n) const
     {
         if (format_.type == 'E' || format_.type == 'G') {
             // print exponent symbol in upper case
             return this->base_policy_type::
                 template exponent<char_encoding::ascii, tag::upper>(sink, n);
         }
         return this->base_policy_type::
             template exponent<CharEncoding, Tag>(sink, n);
     }

     ///////////////////////////////////////////////////////////////////////////
     //  this gets called by the numeric generators at the top level, it allows
     //  to do alignment and other high level things
     template <typename Inserter, typename OutputIterator, typename Policies>
     bool call (OutputIterator& sink, T n, Policies const& p) const
     {
         bool r = false;
         if (format_.flag == '-') {    // left align
             // wrap the given output iterator to allow counting
             karma::detail::enable_counting<OutputIterator> counting(sink);

             // first generate the actual floating point number
             r = Inserter::call_n(sink, n, p);

             // pad the output until the max width is reached
             while(r && int(counting.count()) < format_.width)
                 r = karma::generate(sink, ' ');
         }
         else {                        // right align
             // wrap the given output iterator to allow left padding
             karma::detail::enable_buffering<OutputIterator> buffering(
                 sink, format_.width);

             // first generate the actual floating point number
             {
                 karma::detail::disable_counting<OutputIterator> nocounting(sink);
                 r = Inserter::call_n(sink, n, p);
             }

             buffering.disable();    // do not perform buffering any more

             // generate the left padding
             karma::detail::enable_counting<OutputIterator> counting(
                 sink, buffering.buffer_size());
             while(r && int(counting.count()) < format_.width)
                 r = karma::generate(sink, format_.fill);

             // copy the buffered output to the target output iterator
             if (r)
                 buffering.buffer_copy();
         }
         return r;
     }

     client::format_data format_;
 };

 ///////////////////////////////////////////////////////////////////////////////
 // This is the generator usable in any Karma output format expression, it needs
 // to be utilized as
 //
 //    generate(sink, real("%6.3f"), 3.1415926536);    // prints: ' 3.142'
 //
 // and it supports the format specification as described above.
 typedef karma::real_generator<double, format_policies<double> > real;

 ///////////////////////////////////////////////////////////////////////////////
 int main()
 {
     std::cout << "/////////////////////////////////////////////////////////////\n\n";
     std::cout << "A format driven floating point number generator for Spirit...\n\n";
     std::cout << "/////////////////////////////////////////////////////////////\n\n";

     std::cout << "Give me a printf style format\n";
     std::cout << "Type [enter] to quit\n\n";

     std::string str;
     while (getline(std::cin, str))
     {
         if (str.empty())
             break;

         try {
             std::string generated;
             std::back_insert_iterator<std::string> sink(generated);
             if (!karma::generate(sink, real(str.c_str()), 4*std::atan(1.0)))
             {
                 std::cout << "-------------------------\n";
                 std::cout << "Generating failed\n";
                 std::cout << "-------------------------\n";
             }
             else
             {
                 std::cout << ">" << generated << "<\n";
             }
         }
         catch (std::runtime_error const&) {
             std::cout << "-------------------------\n";
             std::cout << "Invalid format specified!\n";
             std::cout << "-------------------------\n";
         }
     }

     return 0;
 }
	// Copyright (c) 2001-2010 Hartmut Kaiser
	//
	// Distributed under the Boost Software License, Version 1.0. (See accompanying
	// file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)

	// The main purpose of this example is to show how a single container type can
	// be formatted using different output grammars.

	#include <boost/config/warning_disable.hpp>
	#include <boost/spirit/include/qi.hpp>
	#include <boost/spirit/include/karma.hpp>
	#include <boost/fusion/include/adapt_struct.hpp>

	#include <cmath>

	using namespace boost::spirit;

	///////////////////////////////////////////////////////////////////////////////
	// This policy allows to use printf style formatting specifiers for Karma
	// floating point generators. This policy understands the following format:
	//
	// The format string must conform to the following format, otherwise a
	// std::runtime_error will be thrown:
	//
	// %[flags][fill][width][.precision]type
	//
	// where:
	// flags (only one possible):
	// +: Always denote the sign '+' or '-' of a number
	// -: Left-align the output
	// fill:
	// 0: Uses 0 instead of spaces to left-fill a fixed-length field
	// width:
	// number: Left-pad the output with spaces until it is at least number
	// characters wide. if number has a leading '0', that is
	// interpreted as a 'fill', the padding is done with '0'
	// characters instead of spaces.
	// precision:
	// number: Causes the decimal portion of the output to be expressed
	// in at least number digits
	// type (only one possible):
	// e: force scientific notation, with a lowercase "e"
	// E: force scientific notation, with a uppercase "E"
	// f: floating point format
	// g: use %e or %f, whichever is shorter
	// G: use %E or %f, whichever is shorter
	//

	///////////////////////////////////////////////////////////////////////////////
	// define a data structure and a corresponding parser to hold the formatting
	// information extracted from the format specification string
	namespace client
	{
	struct format_data
	{
	char flag;
	char fill;
	int width;
	int precision;
	char type;
	};
	}

	// We need to tell fusion about our format_data struct
	// to make it a first-class fusion citizen
	BOOST_FUSION_ADAPT_STRUCT(
	client::format_data,
	(char, flag)
	(char, fill)
	(int, width)
	(int, precision)
	(char, type)
	)

	namespace client
	{
	///////////////////////////////////////////////////////////////////////////
	// Grammar for format specification string as described above
	template <typename Iterator>
	struct format_grammar : qi::grammar<Iterator, format_data()>
	{
	format_grammar() : format_grammar::base_type(format)
	{
	using qi::uint_;
	using qi::attr;
	using ascii::char_;
	using ascii::no_case;

	format %= '%' >> flags >> fill >> width >> prec >> type;

	// default flags is right aligned
	flags = char_('+') \| char_('-') \| attr(' ');
	fill = char_('0') \| attr(' '); // default fill is space
	width = uint_ \| attr(-1);
	prec = '.' >> uint_ \| attr(3); // default is 3 digits
	type = no_case[char_('e')] \| char_('f') \| no_case[char_('g')];
	};

	qi::rule<Iterator, format_data()> format;
	qi::rule<Iterator, char()> flags;
	qi::rule<Iterator, char()> fill;
	qi::rule<Iterator, int()> width;
	qi::rule<Iterator, int()> prec;
	qi::rule<Iterator, char()> type;
	};
	}

	///////////////////////////////////////////////////////////////////////////////
	// real_policies implementation allowing to use a printf style format
	// specification for Karma floating pointing number generators
	template <typename T>
	struct format_policies : karma::real_policies<T>
	{
	typedef karma::real_policies<T> base_policy_type;

	///////////////////////////////////////////////////////////////////////////
	// This real_policies implementation requires the output_iterator to
	// implement buffering and character counting. This needs to be reflected
	// in the properties exposed by the generator
	typedef boost::mpl::int_<
	karma::generator_properties::countingbuffer
	> properties;

	///////////////////////////////////////////////////////////////////////////
	format_policies(char const* fmt = "%f")
	{
	char const* last = fmt;
	while (*last)
	last++;

	client::format_grammar<char const*> g;
	if (!qi::parse(fmt, last, g, format_))
	throw std::runtime_error("bad format string");
	}

	///////////////////////////////////////////////////////////////////////////
	// returns the overall format: scientific or fixed
	int floatfield(T n) const
	{
	if (format_.type == 'e' \|\| format_.type == 'E')
	return base_policy_type::fmtflags::scientific;

	if (format_.type == 'f')
	return base_policy_type::fmtflags::fixed;

	BOOST_ASSERT(format_.type == 'g' \|\| format_.type == 'G');
	return this->base_policy_type::floatfield(n);
	}

	///////////////////////////////////////////////////////////////////////////
	// returns whether to emit a sign even for non-negative numbers
	bool const force_sign(T) const
	{
	return format_.flag == '+';
	}

	///////////////////////////////////////////////////////////////////////////
	// returns the number of required digits for the fractional part
	unsigned precision(T) const
	{
	return format_.precision;
	}

	///////////////////////////////////////////////////////////////////////////
	// emit the decimal dot
	template <typename OutputIterator>
	static bool dot (OutputIterator& sink, T n, unsigned precision)
	{
	// don't print the dot if no fractional digits are to be emitted
	if (precision == 0)
	return true;
	return base_policy_type::dot(sink, n, precision);
	}

	template <typename CharEncoding, typename Tag, typename OutputIterator>
	bool exponent (OutputIterator& sink, long n) const
	{
	if (format_.type == 'E' \|\| format_.type == 'G') {
	// print exponent symbol in upper case
	return this->base_policy_type::
	template exponent<char_encoding::ascii, tag::upper>(sink, n);
	}
	return this->base_policy_type::
	template exponent<CharEncoding, Tag>(sink, n);
	}

	///////////////////////////////////////////////////////////////////////////
	// this gets called by the numeric generators at the top level, it allows
	// to do alignment and other high level things
	template <typename Inserter, typename OutputIterator, typename Policies>
	bool call (OutputIterator& sink, T n, Policies const& p) const
	{
	bool r = false;
	if (format_.flag == '-') { // left align
	// wrap the given output iterator to allow counting
	karma::detail::enable_counting<OutputIterator> counting(sink);

	// first generate the actual floating point number
	r = Inserter::call_n(sink, n, p);

	// pad the output until the max width is reached
	while(r && int(counting.count()) < format_.width)
	r = karma::generate(sink, ' ');
	}
	else { // right align
	// wrap the given output iterator to allow left padding
	karma::detail::enable_buffering<OutputIterator> buffering(
	sink, format_.width);

	// first generate the actual floating point number
	{
	karma::detail::disable_counting<OutputIterator> nocounting(sink);
	r = Inserter::call_n(sink, n, p);
	}

	buffering.disable(); // do not perform buffering any more

	// generate the left padding
	karma::detail::enable_counting<OutputIterator> counting(
	sink, buffering.buffer_size());
	while(r && int(counting.count()) < format_.width)
	r = karma::generate(sink, format_.fill);

	// copy the buffered output to the target output iterator
	if (r)
	buffering.buffer_copy();
	}
	return r;
	}

	client::format_data format_;
	};

	///////////////////////////////////////////////////////////////////////////////
	// This is the generator usable in any Karma output format expression, it needs
	// to be utilized as
	//
	// generate(sink, real("%6.3f"), 3.1415926536); // prints: ' 3.142'
	//
	// and it supports the format specification as described above.
	typedef karma::real_generator<double, format_policies<double> > real;

	///////////////////////////////////////////////////////////////////////////////
	int main()
	{
	std::cout << "/////////////////////////////////////////////////////////////\n\n";
	std::cout << "A format driven floating point number generator for Spirit...\n\n";
	std::cout << "/////////////////////////////////////////////////////////////\n\n";

	std::cout << "Give me a printf style format\n";
	std::cout << "Type [enter] to quit\n\n";

	std::string str;
	while (getline(std::cin, str))
	{
	if (str.empty())
	break;

	try {
	std::string generated;
	std::back_insert_iterator<std::string> sink(generated);
	if (!karma::generate(sink, real(str.c_str()), 4*std::atan(1.0)))
	{
	std::cout << "-------------------------\n";
	std::cout << "Generating failed\n";
	std::cout << "-------------------------\n";
	}
	else
	{
	std::cout << ">" << generated << "<\n";
	}
	}
	catch (std::runtime_error const&) {
	std::cout << "-------------------------\n";
	std::cout << "Invalid format specified!\n";
	std::cout << "-------------------------\n";
	}
	}

	return 0;
	}